Background

The freshwater snail Lymnaea stagnalis (L. stagnalis) has served as a successful model for studies in the field of Neuroscience. However, a serious drawback in the molecular analysis of the nervous system of L. stagnalis has been the lack of large-scale genomic or neuronal transcriptome information, thereby limiting the use of this unique model.

Results

In this study, we report 7,712 distinct EST sequences (median length: 847 nucleotides) of a normalized L. stagnalis central nervous system (CNS) cDNA library, resulting in the largest collection of L. stagnalis neuronal transcriptome data currently available. Approximately 42% of the cDNAs can be translated into more than 100 consecutive amino acids, indicating the high quality of the library. The annotated sequences contribute 12% of the predicted transcriptome size of 20,000. Surprisingly, approximately 37% of the L. stagnalis sequences only have a tBLASTx hit in the EST library of another snail species Aplysia californica (A. californica) even using a low stringency e-value cutoff at 0.01. Using the same cutoff, approximately 67% of the cDNAs have a BLAST hit in the NCBI non-redundant protein and nucleotide sequence databases (nr and nt), suggesting that one third of the sequences may be unique to L. stagnalis. Finally, using the same cutoff (0.01), more than half of the cDNA sequences (54%) do not have a hit in nematode, fruitfly or human genome data, suggesting that the L. stagnalis transcriptome is significantly different from these species as well. The cDNA sequences are enriched in the following gene ontology functional categories: protein binding, hydrolase, transferase, and catalytic enzymes.

Conclusion

This study provides novel molecular insights into the transcriptome of an important molluscan model organism. Our findings will contribute to functional analyses in neurobiology, and comparative evolutionary biology. The L. stagnalis CNS EST database is available at http://www.Lymnaea.org/.

The freshwater pond snail, Lymnaea stagnalis (L. stagnalis, Linnaeus, 1758), belongs to the phylum Mollusca (Gastropoda, Basommatophora, Pulmonata, Lymnaeidae). Similar to other gastropods such as the marine snail Aplysia californica (A. californica) and the terrestrial snail Helix aspersa, L. stagnalis has served successfully as a model for a wide spectrum of studies in molecular, cellular, and behavioral neurobiology. As compared to the mammalian brain with 1011 neurons and Drosophila melanogaster (D. melanogaster) ganglia comprising 200,000 neurons, L. stagnalis has a relatively simple central nervous system (CNS) consisting of a total of ~20,000 neurons, many of them individually identifiable, organized in a ring of interconnected ganglia (Figure 1). Most neurons of the L. stagnalis CNS are large in size (diameter: up to ~100 μm), thus allowing electrophysiological dissection of neuronal networks that has yielded profound insights in the working mechanisms of neuronal networks controlling relatively simple behaviors such as feeding [1, 2], respiration [3, 4], locomotion [5], and reproduction [6, 7]. Studies using the CNS of L. stagnalis as a model have also identified novel cellular and molecular mechanisms in neuronal regeneration [8–11], synapse formation [12–15], synaptic plasticity [16], learning and memory formation [17, 18], the neurobiology of development [19–22] and aging [23–25], the modulatory role of neuropeptides [26–28], and adaptive responses to hypoxic stress [29–32]. Contrasting the large body of dedicated studies in neurobiology, the molecular analysis of genomic information of L. stagnalis is rather limited. The only available transcript sequence data set of L. stagnalis includes 1,320 expressed sequence tags (ESTs; derived from 771 different sequences) generated from L. stagnalis CNS libraries that were not normalized [33]http://www.nematodes.org/NeglectedGenomes/MOLLUSCA/. The lack of adequate transcriptome and genome information of L. stagnalis is currently a large drawback for the use of this species in functional and comparative molecular studies [34].

Figure 1

The dissected central ring ganglia ofLymnaea stagnalis. LBuG and RBuG: left and right buccal ganglia; LCeG and RCeG: left and right cerebral ganglia; LPeG and RPeG: left and right pedal ganglia; LPIG and RPIG: left and right pleural ganglia; LPaG and RPaG: left and right parietal ganglia; VG: visceral ganglion. Scale bar: 1 mm.

Mollusks have more than 100,000 extant species and comprise the second largest phylum after the Arthropods [35, 36], indicating the phylum has been highly adaptive to environmental changes since its origin in the Cambrian period [35]. The gastropods are the largest group within the mollusca encompassing over 80% of the extant species [37]. However, in contrast to their abundance and importance in neurobiology, large-scale genomic information relating to neuronal function is limited to one species, A. californica [38]. There are two additional on-going genomic sequencing projects of mollusks: Lottia gigantea (L. gigantean; http://genome.jgi-psf.org/Lotgi1/Lotgi1.download.html) and Biomphalaria glabrata (B. glabrata; http://www.ncbi.nlm.nih.gov/sites/entrez?Db=genomeprj&cmd=ShowDetailView&TermToSearch=12878); however, the genomic sequence information from these two species is currently not yet available. As L. stagnalis and A. californica genera are believed to have diverged over 600 million years ago, the sequencing of the CNS transcriptome from L. stagnalis holds significant promise for functional, evolutionary, comparative and environmental studies of Mollusks and other species.

We have carried out transcriptome sequencing of a normalized cDNA library constructed from the L. stagnalis CNS. This study provided 10,375 EST sequences, which cluster to 7,712 unique sequences. Despite a substantial fraction of the cDNAs being homologous to A. californica sequences in the existing known sequence database, data analysis revealed that the majority of the L. stagnalis cDNAs are novel and have no known homologues. Therefore, our findings argue for the sequencing of the full transcriptome of this species. This study forms the basis for functional genomic research of L. stagnalis not only as a model system for various areas of neuroscience research but also for general evolutionary and comparative genomics.

Overall statistics of the L. stagnalis cDNA library

Double-end sequencing was performed on 5376 clones that were randomly selected from the L. stagnalis CNS normalized library. After deleting the vector sequences, we successfully obtained a total of 10,375 EST sequences (GenBank EST Acc. number: ES291075 - ES291826; ES570937 - ES580561), which cluster to 7,712 unique sequences. The median length of the sequence reads was 838 nucleotides (mean 803 nt), the shortest being 20, and the longest cDNA being 1044 nucleotides. In fact, close to 90% of the raw sequences (9272) are longer than 700 nucleotides (Figure 2A). The mean and median G+C content of the cDNA library is 36%.

Figure 2

Overall statistics of theLymnaeacDNA library.(A) Distribution of the sequence length of the cDNA sequences before and after assembly by the CAP3 program. (B) Distribution of the maximum length of translated peptide sequences.

Post-processing and sequence assembly

To estimate the level of sequence redundancy and overlap within our library, we first ran a BLAST search against the raw sequence library itself, and noticed that a large number of sequences overlap, most likely as the result of bi-directional sequencing. We then assembled the cDNA sequences by using the CAP3 software [39], which identified 6,139 singlet sequences, and 1,573 clusters (default parameters were used as suggested by the authors of CAP3), yielding 7,712 sequences with unique cDNA sequences. The median length of these assembled cDNAs is 847 nucleotides (with mean of 862 nt), the shortest being 20 nucleotides, and longest being 3,227 nucleotides. Figure 2A compares the distribution of the sequence length before and after the sequence assembly. We next translated the 7,712 assembled cDNA sequences into six possible open reading frames (ORFs), and selected the largest ORF for each sequence. Figure 2B shows that 3,248 cDNA sequences contain ORFs that are longer than 100 amino acids, which is a strong indication that these cDNAs cover protein coding regions.

Comparison with previously published L. stagnalis EST sequences

Previously, Davison and Blaxter [33] sequenced a small set of ESTs from unnormalized libraries of L. stagnalis CNS and the EST set contained 1,320 sequences with an average length of 665 nt. Using these data as query we searched for homology hits in our cDNA library. Using a stringent cutoff requiring sequence identity of at least 90% and a minimum alignment length of 30 nucleotides, 509 (38.6%) sequences in our library have a hit in the previous library, and 711 (54%) of the sequences in the earlier library have a hit in ours. These differences may be accounted for 1) by the sizes of the libraries used, and 2) the previous ESTs may include redundant sequences.

We next ran BLASTx searches (using translated nucleotides as a query to search against protein sequence library) and mapped the L. stagnalis cDNA sequences to the NCBI (http://www.ncbi.nlm.nih.gov/; up to May, 2009) non-redundant protein library (nr), which is commonly used as the principle target database to search for protein homologies. This database was constructed by pooling the sequences from the following databases, followed by clustering and removing redundant entries: translated protein coding region of all the sequence entries in the GenBank, RefSeq database (high quality proteins from human and mouse), PDB (protein structure database), SwissProt, PIR (Protein Information Source), PRF (Protein Research Foundation).

In addition, we carried out BLAST searches against the NCBI non-redundant nucleotide sequence data base (nt), which stores all the nucleotide sequences submitted to GenBank to account for the possibility that some of the shorter cDNA sequences were derived from 3' or 5' untranslated regions (UTR) of mRNA transcripts instead of mapping to the protein coding region. This also covers cDNAs that are derived from non-coding RNA transcripts such as rRNA.

The results of these two BLAST searches are plotted in Figure 3. For each e-value cutoff, we divided the L. stagnalis sequences into four categories: (i) having a hit in "nr (protein)" but not in "nt (nucleotide)", (ii) having a hit in both "nr" and "nt", (iii) having a hit in "nt" but not in "nr", and (iv) having a hit in neither "nr" nor "nt". Our prediction was that the third category likely represents 3' or 5' UTRs or noncoding RNA transcripts. A closer inspection of the reads in category (iii) revealed that most of these reads that actually map to EST or cDNA sequences in "nt" do not have a corresponding entry in "nr", mostly because that these nt sequences are either too short or do not contain an open reading frame. The fourth category, on the other hand, likely represents novel sequences that only exist in L. stagnalis. However, it is also possible that some of the sequences in this category are reads from the 5' or 3' UTRs or from non-coding transcripts. The analysis was restricted to those cDNA sequences that are longer than 100 or 500 bases and the results are shown in Figure 3A and 3B.

Using an e-value cutoff of 1e-6, only 34% (2,606) of the L. stagnalis cDNAs had a statistically significant hit to a protein in the non-redundant database (Figure 3A). Even at an e-value cutoff of 0.001, 52% (3,930) of L. stagnalis cDNA sequences longer than 100 bases (Figure 3A) and 50% (3,630) of cDNA sequences longer than 500 bases (Figure 3B) have no significant BLAST matches in the non-redundant protein and nucleotide databases. This is likely caused by the relatively low coverage of DNA or genomic sequences from the Mollusca phylum in the current sequence databases, including the A. californica and B. glabrata EST databases.

We next investigated the phylogenetic distribution of the top BLAST hits. For each L. stagnalis cDNA, we found the phylum of its best BLAST match, and then catalogued the best matches according to their phylogenetic origin and counted the matches for each phylum. Table 1 shows the frequency of the matches with an e-value cutoff 1e-10 as used by Moroz et al (2006) [38]. The hits to chordate sequences are significantly higher than the other phyla, including Lophotrochozoan. However, this raises a question about the usefulness of such an analysis for sequence mapping as the frequency of hits is obviously associated with the number of the sequences available in the database. The number of sequences from each of the metazoan phyla in the database is largely variable as the different phyla are not all equally covered. Thus, such a presentation has the potential to introduce a serious bias towards phyla that are better presented in the databases.

Table 1

Phylogenetic distribution of the top hits in the NCBI nr library

Phylogenetic group

Number of cDNAs

(e-value < 1e-10)

Chordata

944

Arthropoda (e.g. insects and Crustaceans)

562

Lophotrochozoan, including Mollusca, Annelida (segmented worms)

302

Echinodermata

273

Cnidaria (e.g. Hydra and jelly fish)

212

Nematoda (including C. elegans)

57

Platyzoa

47

Bacteria

46

Plants

41

Fungi

33

Total

2583

Comparison with A. californica sequences

A. californica is currently the only other mollusk species for which an effort has been made to obtain the complete CNS transcriptome sequences [38]. To better understand the sequence diversity between these mollusk species, we compared the L. stagnalis cDNA sequences (7712 sequences with an average length of 862 nucleotides) with the EST sequences from A. californica reported by Moroz et al [38]. The published A. californica EST dataset includes 199,689 sequences surveyed from a wide range of tissues, with an average length of 563 nucleotides. Table 2 provides data on the cumulative populations of hits between the L. stagnalis and A. californica ESTs. We first conducted the Blastn analysis between the two datasets. At e-value cutoff of 1E-6, approximately 13% of the L. stagnalis cDNAs has a BLASTn hit in the A. californica EST library, and approximately 6% of the A. californica library has a match in this L. stagnalis cDNA library (Table 2). At a less stringent e-value cutoff of 0.01, hits for an additional ~7% of the L. stagnalis cDNAs were found in the A. californica EST library, and an additional ~7% of the A. californica library produced hits in this L. stagnalis cDNA library (Table 2). Because these two species are distantly related organisms, the low hits resulted from our Blastn analysis may be simply due to the difference in their genetic codes. We thus carried out a tblastx analysis to search a translated nucleotide database using a translated nucleotide query. As presented in Table 2, at e-value cutoff of 1e-6, the tblastx hits of L. stagnalis ESTs in A. californica database reached 28.9%, whilst the percentage of tblastx hits of A. californica sequences in the L. stagnalis EST database was 11.9%. Taking together, these data indicate a relative low percentage of matches between A. californica and L. stagnalis EST sequences.

Comparison of blastn (search a nucleotide database using a nucleotide query) and tblastx searches (search translated nucleotide database using a translated nucleotide query).

It is possible that some of these L. stagnalis cDNAs are not expressed at high levels in A. californica and are not detectable in the transcriptome studies; therefore we compared the L. stagnalis cDNA sequences against the A. californica genomic trace files, downloaded from NCBI GenBank. At the e-value cutoff of 1e-6, about 13% of the L. stagnalis cDNAs have a hit in the A. californica trace library (Table 3). Another possible explanation for the relatively low match between L. stagnalis and A. californica could be that a large proportion of corresponding ESTs match to different parts of the same (orthologous) mRNAs and are therefore not identified as a match. To test this we took the 1,074 L. stagnalis ESTs with a best scoring match to NCBI nr and ran the respective NCBI nr match sequences against the A. californica EST database using a tBLASTx search. We expected that orthologous non-overlapping ESTs from both species would thus be bridged by their corresponding longer NCBI nr sequence match. Surprisingly only ~0.2% (2 out of 1074) of the L. stagnalis ESTs could be matched with an A. californica EST with an e-value ≤ 0.01. Although there are several limitations with respect to comparing EST datasets, especially when they are relatively small in size, these findings together seem to suggest that there is high sequence divergence between A. californica and L. stagnalis.

Table 3

Blast hits in the A. californica trace library using the L. stagnalis cDNA as query

Blast E-value

Number of hits

%

cumulative

%

1.E-20

264

3.42%

264

3.42%

1.E-10

405

5.25%

669

8.67%

1.E-06

327

4.24%

996

12.91%

1.E-03

455

5.90%

1,451

18.81%

0.01

450

5.84%

1,901

24.65%

0.1

1,622

21.03%

3,523

45.68%

1

3,387

43.92%

6,910

89.60%

>1

802

10.40%

7,712

100.00%

Sum

7,712

Comparison with Biomphalaria glabrata sequences

The freshwater snail Biomphalaria glabrata (B. glabrata) belongs to the family Planorbidae of the pulmonate gastropod mollusk. Recently the whole genome sequencing of B. glabrata has been completed http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=6526, however, the trace sequences have not yet been assembled. Currently, there are 19,523 EST sequences of various B. glabrata tissues, not limited to the CNS, deposited into the GenBank. We thus compared the B. glabrata EST sequences with our L. stagnalis EST sequences. Our blastn and tblastx analyses are shown in Table 4. At e-value cutoff of 1e-6, the rate of Blastn hits of L. stagnalis ESTs in B. glabrata database was ~5% and the rate of tblastx hits was ~11%. In contrast, the Blastn hits of B. glabrata ESTs in our L. stagnalis database was ~12% and the tblastx hits were ~17%. These results indicate 1) that there is a significant level of redundancy in the B. glabrata EST library because many B. glabrata ESTs match to the same L. stagnalis sequences; 2) there is a relative low match between B. glabrata and L. stagnalis EST sequences, suggesting a substantial difference between the transcriptomes of the two animals.

Table 4

Blast hits in the B. glabrata EST library using the L. stagnalis cDNA as query

Blast E-value

Number of L. stagnalis ESTs having a blast hit in B. glabrata library

Number of B. glabrata ESTs having a blast hit in L. stagnalis

Blastn

Tblastx

Blastn

Tblastx

1e-10

307 (4%)

682 (8.8%)

2098 (10.7%)

2689 (13.8%)

1e-6

375 (4.9%)

868 (11.3%)

2372 (12.1%)

3378 (17.3%)

1e-03

594 (7.7%)

1288 (16.7%)

3244 (16.6%)

4891 (25.1%)

Comparison with other model organisms

We investigated the occurrence of the L. stagnalis cDNAs in three different organisms: the model organisms nematode worm (C. elegans) and fruitfly (D. melanogaster), and human. We ran BLAST searches against the combined protein, mRNA, and noncoding RNA libraries in worm, fruitfly and human respectively; the results are shown in Figure 4. As seen in Figure 4A, with an e-value cutoff at 1e-6, 1,694 L. stagnalis cDNA sequences have a BLAST hit to a protein, an mRNA, or a RNA sequence in worm; 1,915 cDNAs have a hit in fly, and 2,065 cDNAs have a hit in human. Remarkably, 70% (5463) of the cDNAs do not have any BLAST hit in any of these three organisms. Similar results are shown in Figure 4B, with a BLAST cutoff at 0.01. In this case, 54% (4,179) of the cDNA sequences do not have any BLAST hit. This relatively low concordance reflects the substantial evolutionary distance between L. stagnalis and the three species from different animal phyla.

Gene Ontology Mapping

We mapped the cDNA sequences to the UniProt protein database, since this is the only comprehensive database for which GO annotation data is available. Using the e-value cutoff of 1e-6, 2,242 (29%) sequences can be mapped to a UniProt entry; using an e-value of 1e-10, 2,038 (26%) can be mapped to a UniProt entry. We identified the corresponding Gene Ontology entries mapped to GOslim terms by using the tools provided by the GOA website http://www.ebi.ac.uk/GOA/. Table 5 shows the most frequently occurring GO functional categories.

Table 5

GO category distribution of the Lymnaea cDNAs

GO terms

GO terms

cDNA frequency

GO:0005515

protein binding

723

GO:0016787

hydrolase activity

350

GO:0016740

transferase activity

237

GO:0003824

catalytic activity

221

GO:0016491

oxidoreductase activity

187

GO:0005198

structural molecule activity

138

GO:0016874

ligase activity

90

GO:0030234

enzyme regulator activity

78

GO:0030528

transcription regulator activity

64

GO:0005215

transporter activity

51

GO:0015075

ion transmembrane transporter activity

45

GO:0004871

signal transducer activity

45

GO:0016829

lyase activity

44

GO:0004872

receptor activity

44

GO:0045182

translation regulator activity

42

GO:0016853

isomerase activity

38

Total

2406

Alignment of known presynaptic genes

We identified a number of genes from the L. stagnalis library that are functionally related to presynaptic activity and other neuronal functions. We then generated multiple sequence alignments of these L. stagnalis proteins with their orthologous genes from other species and generated the corresponding phylogenetic trees (Figure 5, 6, and 7). We found that, as expected, the L. stagnalis sequences are most closely related to their orthologs in A. californica. Typical examples are the clathrin adaptor-protein complex 2 (AP-2) mu-1 subunit and the clathrin AP-1 theta-1 subunit shown in Figure 5 and Figure 6, respectively. The phylogenetic trees clearly show the conservation of these proteins across species. The L. stagnalis orthologue is more closely related to A. californica than other invertebrates and is distant from vertebrates. Intriguingly, L. stagnalis has an ortholog of the vertebrate syntaxin 7 gene, but its equivalent has so far not been found in the A. californica library (Figure 7).

Figure 5

Protein sequence alignment and phylogenetic tree of clathrin adapter-protein-2 (AP-2) mu-1 subunit. The alignment (A) and the phylogenetic tree (B) were generated by Clustalw. FPS013.CR.J08 is the Lymnaea orthologue identified in this study.

Figure 6

Protein sequence alignment and phylogenetic tree of clathrin adapter-protein-1 (AP-1) theta-1 subunit. The alignment (A) and the phylogenetic tree (B) were generated by Clustalw. FPS0112.CR.F02 is the Lymnaea orthologue identified in this study.

Figure 7

Protein sequence alignment and phylogenetic tree of syntaxin 7. The alignment (A) and the phylogenetic tree (B) were generated by Clustalw. FPS0110.CR.A09 is the Lymnaea orthologue identified in this study.

In summary, we reported in this study the CNS expressed cDNA sequences of 5376 randomly selected clones from a normalized CNS cDNA library, thus providing what is currently the largest database of L. stagnalis cDNA sequences. Because molluscan species have not been frequently used in the sequencing projects, this is currently the second largest CNS transcriptome study in the entire Mollusca phylum. Although the transcriptome information is far from complete, we found only ~25% BLAST hits of L. stagnalis cDNA sequences in A. californica sequences, which suggests substantial genetic differences between these two gastropod mollusks. This argues for further large scale sequencing of L. stagnalis that will shed light on the extent of diversification of the genome in both molluscan species.

Normalized cDNA library

In this study we used a normalized cDNA library to reduce the high variation among the abundant clones, thus increasing the probability of sequencing rare transcripts [40]. We found that over 90% of the sequences are between 700 and 1000 bp long, indicating the overall good quality of the sequencing processes. We have sequenced 5376 clones and obtained 10,375 EST sequences which cluster to 7,712 unique sequences. The comparison between our library and the previous published Lymnaea EST sequences generated from a non-normalized library [33] showed that 509 (38.6%) sequences in our library have a hit in the previous library, and 711 (54%) of the sequences in the earlier library have a hit in ours. The higher percentage of hits using the previous library to search the present ESTs is likely due to that 1) the previous sequencing of an unnormalized EST library includes a large proportion of redundant sequences; and 2) this study sequenced ESTs from normalized libraries which reduces the probability of redundant sequences, and thus yielded a higher coverage. In addition, the previous library comprised sequences from the 5' end of transcripts, whereas the present EST database includes a mix of 5' and 3' sequences. It thus is also possible that a proportion of sequences of the previous ESTs generate more than one hit in our database.

Novel transcripts in L. stagnalis

It is intriguing that a large proportion of the L. stagnalis cDNAs contain novel sequences that apparently have no significant match in any of the existing databases. In fact, as shown in Figure 3B, even after restricting analyses to sequences that are longer than 500 nucleotides and a less restrictive BLAST e-value cutoff of 1e-6, approximately half of the cDNAs (3,630) have no homologous sequences in the existing databases. Many of these novel transcripts can also be translated into long sequences of amino acids. For example one cDNA (Contig 596; Supplementary Material, http://www.Lymnaea.org/) has 3216 nucleotides containing 505 consecutively translated amino acids. Interestingly, the closest sequence homolog for this sequence is a RNA polymerase in potato (gi|68124015|emb|CAJ01915.1| DNA-directed RNA polymerase [Solanum tuberosum]). Nevertheless, the large collection of gene sequences identified in this study include structural proteins, heat shock proteins, transcription factors, ion channels, receptors, and protein kinases.

Alignment and phylogenetic trees

We have aligned a number of presynaptic protein sequences from L. stagnalis to those of other model organisms. The L. stagnalis presynaptic protein sequences tested here are highly homologous to other species, consistent with the notion that both invertebrates and vertebrates share similar molecular mechanisms of synaptic transmission (see [41]). Interestingly, we identified a syntaxin 7 sequence in the L. stagnalis CNS transcriptome. Syntaxin 7 is one of the endosomal SNARE (soluble N-ethylmaleimide-sensitive factor attachment protein receptors) proteins that may be involved in a conserved late endosomal fusion pathway [42, 43]. Notably, this protein has so far not been reported in A. californica.

Our results demonstrate that the L. stagnalis CNS transcriptome data complement the transcriptome sequencing project of A. californica [38]. Based on the A. californica CNS sequence data, we expect a total of ~20,000 neuronal gene products in the L. stagnalis CNS. We currently obtained 2,406 transcripts corresponding to known biological processes. These annotated transcripts contribute 12% of the predicted transcriptome size. The hits of L. stagnalis sequences to the A. californica transcriptome are ~29% (e-value: 1E-6; tblastx), and an additional 9% were found to match A. californica sequences with an e-value cutoff at 0.01. Amongst 7712 L. stagnalis sequences tested, over 97% (7484 out of 7712 sequences) of them have lengths greater than 300 nucleotides, and over 42% (3248 out of 7712) sequences contain ORFs that are longer than 100 amino acids. Assuming that the A. californica EST set has a good coverage [38], it is a somewhat low match which indicates the possibility that the CNS transcriptome sequences of the two species are considerably different. Although both species are classified as heterobranches [44] within the gastropods, the two branches diverged over 600 million years ago. Thus it is not surprising to see these apparently large transcriptome sequence variations between these two species. However, our sequencing effort comprises only a fraction of the neuronal transcriptome and a larger scale sequencing project is required in order to make a full comparison between these two species.

This study currently provides the largest database of L. stagnalis CNS EST sequences, and demonstrates the substantial genetic differences between two gastropod mollusks, L. stagnalis and A. californica. This study establishes a firm basis for functional genomic research in this species, for comparative and environmental genomics, and for identification of novel proteins important for neuronal functions, thus directly supporting and advancing ongoing functional work in this and related model systems.

Animals

L. stagnalis were obtained from a culture at the VU University, Amsterdam, and were raised and maintained in aquaria at the University of Calgary, as previously described [13, 45]. Animals were kept in water at 20°C under a 12 hr light/dark cycle, and fed green leaf lettuce twice a week. Two-month old snails having shell lengths of 15 to 20 mm were used in this study. Specifically, the snails were anesthetized with 10% (v/v) Listerine for 10 min. The central ring ganglia and attached buccal ganglia were dissected out and prepared for total RNA extraction. Three central ring ganglia were used for total RNA extraction.

cDNA synthesis and cDNA library normalization

cDNA synthesis and normalization were carried out by Bio S&T Inc. (Montreal, QC, Canada). Specifically, total RNA was extracted from snail ganglia using the modified Trizol method (Invitrogen, USA). Purification of mRNA was carried out using Oligotex mRNA kit (Qiagen, USA), and cDNA synthesis using the SMART™ cDNA library construction kit (Clontech, USA). The clones contain SfiI-A and SfiI-B restriction sites, which allowed directional cloning. Full-length cDNA was synthesized with two set of primers for driver and tester cDNA. Single-stranded cDNA was used for hybridization instead of double-stranded cDNA [40]. Excess amount of sense-stranded cDNA was hybridized with antisense-stranded cDNA. After hybridization, duplex structures were removed by hydroxyapatite chromatography. Normalized tester cDNA was re-amplified with the tester specific primer L4N without amplification of the driver cDNA that cannot be amplified using the L4N primer.

cDNA normalization efficiency was strictly monitored by Bio S & T Inc. (Montreal, QC, Canada). Specifically a parallel normalization of an internal control was performed in addition to the normalization of the cDNA population. In the parallel normalization, a modified reporter gene (chloramphenicol resistance gene with same adaptor-primer sequences) was added to the cDNA population before normalization at a desired redundancy rate (e.g. 1.0%) as a control. cDNA was cloned using a modified pBluescript SK-vector (MBI-Fermentas, Canada). Because pBluescript is ampicillin resistant, the percentage of this control gene is determined before and after normalization. The frequency of chloramphenicol resistant clones was determined and used to estimate the reduction during normalization. In this study, reduction was 40×.

Following normalization, ss-cDNA were amplified by PCR and purified. Re-amplified cDNAs were then subjected to SfiI digestion and size fractionation in a 1% agarose gel. cDNA fragments larger than 0.5 Kb were purified for cloning. The cloning vector was a modified pBluescriptII SK-with SfiI A&B inserts between EcoRI and XhoI. The ligated cDNAs were then transformed into DH10B (Invitrogen, USA). The clones were arrayed in a one clone/well format and amplified by overnight culture. The average insert size was 1.5 kb based on a test sample of 20 random clones. cDNA clones were prepared as glycerol stock in 384-well plates for sequencing.

DNA Sequencing

Double-end cDNA sequencing was carried out by the Genome Sciences Centre at the British Columbia Cancer Agency (Vancouver, BC, Canada) using the Sanger sequencing method. For sequencing of 5'-ends, T3 (or M13F) primer was used; for sequencing of 3'-ends, T7 (or M13R) primer was used. The sequences listed are all in the forward strand, 5' to 3'.

Sequence analysis and bioinformatics

The raw cDNA sequences were subjected to 5'-trimming to eliminate the vector and 3'-trimming to eliminate low quality portions. The sequences were then clustered and assembled into 7712 sequences using the program CAP3 [39]. We used the BLAST program [46] to search for homology sequences in the following sequence databases: NCBI non-redundant protein (nr) and nucleotide (nt) databases, Swissprot protein database, and EST databases including the previously published EST library of A. californica [38]. We wrote PERL scripts to conduct the subsequent bioinformatic analyses (available upon request).

Acknowledgements

We thank Dr. Mike Fainzilber from the Weizmann Institute of Science for his support, and comments to this study. We thank Mr. Wali Zaidi from the University of Calgary for technical assistance with ganglia isolation. We acknowledge funding support from the Weizmann Institute of Science to MF; the NSERC (Canada) Discovery grants to GES, JIG, LTB, RPC (#38863-07), WW (238920), and ZFP (249962-07); the BBSRC (UK) to VAS; SPARC award to MSY; CIHR (Canada) operating grants to JC, NIS, WW (IAP-84665), and ZFP (MOP-151437); IBIVU to PvN.

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Authors' contributions

ZPF and NN carried out the molecular genetic studies; ZZ conducted the bioinformatics analysis; ZPF, ZZ, and NN participated in the sequence alignment; ZPF and ZZ drafted the manuscript; ZPF, ZZ, REVK, VAS, RPC, and ABS participated in producing the final version of the manuscript. KJ developed the sequence database. ZPF, REVK, NIS, and ABS participated in the design of the study. ZPF, NIS and ABS conceived of the study, and ZPF coordinated the study. All authors read, edited and approved the final manuscript.

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